Process Based Antenna Configuration

ABSTRACT

Techniques for process based antenna configuration are described, and may be implemented via a wireless device to identify different usage scenarios and to adapt antenna configurations to optimize wireless performance based on the scenarios. For instance, the described techniques enable a wireless device to be calibrated for wireless communication by identifying different obstruction states of a wireless device that correspond to ways that the wireless device is held (e.g., grasped) by a user in different scenarios. The obstruction states are then correlated to antenna positions in the wireless device to prioritize (e.g., activate) antennas that are relatively unobstructed, such as by activating unobstructed antennas and/or deactivating obstructed antennas. Further, calibration can take into specific processes (e.g., applications) and specific users to calibrate an optimize wireless performance based on ways in which a user typically interacts with a process.

RELATED APPLICATION

This application is a divisional of and claims priority to U.S. patentapplication Ser. No. 16/792,739, filed 17 Feb. 2020 and titled “ProcessBased Antenna Configuration,” the disclosure of which is herebyincorporated by reference in its entirety herein.

BACKGROUND

Wireless communication is ubiquitous and is used for a multitude ofpurposes, including wireless voice and data communication. Further,wireless protocols are constantly evolving to provide increased servicelevels for wireless users. For instance, recent developments in wirelesstechnology have greatly increased the rate at which information can betransmitted wirelessly. One example of such a development is the 5Gwireless cellular technology (e.g., 5G New Radio (NR)), which typicallyachieves higher data rates than previous wireless technologies. Suchrecently developed technologies achieve increased data rates at least inpart by utilizing higher frequency wireless spectrum than previoustechnologies, such as 3.5 gigahertz (GHz) and higher. In fact, someimplementations of these wireless technologies use extremely highfrequency (EHF) frequencies, such as millimeter wave (mmWave)frequencies. While higher data rates can be achieved, such technologiesexhibit a number of implementation challenges, such as increaseddirectionality. Further, higher frequency wireless technologies canexperience higher susceptibility to signal obstruction caused byphysical interference, such as due to interference caused by a usergrasping a device.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects of process based antenna configuration are described withreference to the following Figures. The same numbers may be usedthroughout to reference similar features and components that are shownin the Figures:

FIG. 1 illustrates an example environment in which aspects of processbased antenna configuration can be implemented.

FIG. 2 depicts a scenario for performing aspects of a wirelesscalibration process for a wireless device in accordance with one or moreimplementations.

FIG. 3 depicts a scenario for identifying different device states forcalibrating the wireless device in accordance with one or moreimplementations.

FIG. 4 depicts a scenario for generating an occlusion pattern as part ofa calibration process in accordance with one or more implementationsdescribed herein.

FIG. 5 depicts a scenario for determining antenna state as part of acalibration process in accordance with one or more implementationsdescribed herein.

FIG. 6 depicts a scenario for detecting a grip change during acalibration process in accordance with one or more implementationsdescribed herein.

FIG. 7 depicts a scenario for incorporating a change in obstructionstate into a calibration process in accordance with one or moreimplementations described herein.

FIG. 8 depicts a scenario for generating a representation of devicestate ascertained as part of a calibration process in accordance withone or more implementations described herein.

FIG. 9 depicts a method for calibrating wireless performance of awireless device in accordance with one or more implementations describedherein.

FIG. 10 depicts a method for performing tasks while positioned at anoptimal position for wireless communication in accordance with one ormore implementations described herein.

FIG. 11 depicts a method for configuring antennas of a wireless devicein accordance with one or more implementations described herein.

FIG. 12 depicts a method for configuring antennas of a wireless devicein accordance with one or more implementations described herein.

FIG. 13 depicts a method for configuring antennas of a wireless devicein accordance with one or more implementations described herein.

FIG. 14 illustrates various components of an example device that canimplement aspects of process based antenna configuration.

DETAILED DESCRIPTION

Techniques for process based antenna configuration are described, andmay be implemented via a wireless device to identify different usagescenarios and to adapt antenna configurations to optimize wirelessperformance based on the scenarios. Generally, the described techniquesenable the wireless device to be calibrated for wireless communicationby identifying different obstruction states of a wireless device thatcorrespond to how portions of a wireless device are obstructed based ondifferent usage scenarios. Obstruction states, for instance, representways that a wireless device is held (e.g., grasped) by a user indifferent scenarios. The obstruction states are then correlated toantenna positions in the wireless device to prioritize (e.g., activate)antennas that are relatively unobstructed, such as by activatingunobstructed antennas and/or deactivating obstructed antennas. Further,calibration can take into accounts specific processes (e.g.,applications) and specific users to calibrate an optimize wirelessperformance based on ways in which a user typically interacts with aprocess.

Consider, for example, a scenario where a user launches an applicationon a wireless device and holds the wireless device is a particular waywhile interacting with the application. For instance, some applicationsmay provide a preferable user experience in a portrait orientation of awireless device (e.g., an email application), whereas other applicationsare more suited to a landscape orientation, e.g., a video playerapplication. Thus, depending on application context and userpreferences, a user may grasp a device in different ways to achieve adesired viewing and/or interaction perspective. Accordingly, techniquesdescribed herein enable device calibration to adapt antenna performanceto these different interaction scenarios. For instance, when anapplication is launched on a wireless device (e.g., for the first time),a calibration process is initiated that detects how a user holds thewireless device while interacting with the application. Generally, thiscan be implemented by collecting sensor data that describes how a usergrasps the wireless device, such as sensor data from contact-sensingsensors that detect regions of the wireless device that are in contactwith the user. The different contact regions can then be correlated toantenna locations of the wireless device to identify antennas that maybe occluded by the user's grasp and antennas that may be partially orfully free from occlusion.

Based on the calibration process, a state record can be generated thatidentifies the application and the user, and that identifies an antennastate for the antennas. The antenna state, for example, indicates foreach antenna whether the antenna will likely exhibit good wirelessperformance based on this usage scenario (e.g., is likely unobstructed),or whether each antenna may exhibit poor wireless performance, e.g., islikely obstructed. Accordingly, when the application is subsequentlyactive on the wireless device, the state record can be utilized todetermine which antennas to maintain in an active state (e.g., anunobstructed antenna) and which antennas to maintain in an inactivestate, e.g., obstructed antennas. This not only increases wirelessperformance of the wireless device by prioritizing antennas that arelikely to provide better wireless signal reception and/or transmission,but also conserves power resources (e.g., battery charge) by maintainingantennas that are likely to perform poorly in an inactive state.Further, once a state record for a particular process (e.g., applicationor system process) is generated, the state record can be utilized toproactively adapt antenna state when the process is implemented on awireless device, such as when a user selects the application to beexecuted. For instance, instead of relying on conventional reactiveprocesses that monitor antenna performance and respond to changes inantenna performance which may result in wireless performance degradationdue to lag time in responding to such changes, the described techniquesproactively configure individual antennas based on process state, thusavoiding such performance interruptions.

While features and concepts of process based antenna configuration canbe implemented in any number of different devices, systems,environments, and/or configurations, aspects of process based antennaconfiguration are described in the context of the following exampledevices, systems, and methods.

FIG. 1 illustrates an example environment 100 in which aspects ofprocess based antenna configuration can be implemented. The exampleenvironment 100 includes a wireless computing device (“wireless device”)102 that is connectable to wireless networks 104. In this particularexample, the wireless device 102 represents a portable device that canbe carried by a user 106, such as a smartphone, a tablet device, alaptop, a wearable computing device, (e.g., a smartwatch or a fitnesstracker), and so forth. These examples are not to be construed aslimiting, however, and the wireless device 102 can be implemented in avariety of different ways and form factors. Further example attributesof the wireless device 102 are discussed below with reference to thedevice 1400 of FIG. 14.

The wireless device 102 includes various functionality that enables thewireless device 102 to perform different aspects of process basedantenna configuration discussed herein, including a connectivity module108 and a sensor system 110. The connectivity module 108 representsfunctionality (e.g., hardware and logic) that enables the wirelessdevice 102 to communicate wirelessly, such as for wireless data andvoice communication. The connectivity module 108, for instance, includesfunctionality to support different wireless protocols, such as wirelesscellular (e.g., 3G, 4G, 5G), wireless broadband, Wireless Local AreaNetwork (WLAN) (e.g., Wi-Fi), Wi-Fi Direct, Neighborhood AwarenessNetworking (NAN), wireless short distance communication (e.g.,Bluetooth™ (including Bluetooth™ Low Energy (BLE)), Near FieldCommunication (NFC)), and so forth. The connectivity module 108 alsoincludes antenna modules 112 and device connectivity data (“devicedata”) 114.

The antenna modules 112 represent functionality (e.g., hardware andlogic) for enabling the wireless device 102 to send and receive wirelesssignal, such as for wireless connectivity to the wireless networks 104.At least some individual antenna modules 112, for instance, each includea physical antenna device that is operable to receive wireless signaltransmitted by the wireless networks 104, and to transmit wirelesssignal for receipt by the wireless networks 104. The antenna modules 112may include other hardware and logic, for as for adapting operatingparameters of physical antennas. In at least one implementation, atleast some of the antenna modules 112 represent antennas withoutintegrated logic, such as patch antennas and/or arrays of antennas thatare communicatively connected to the connectivity module 108. In atleast some implementations, the wireless device 102 may employ instancesof the antenna modules 112 physically arranged at different locations onthe wireless device 102, such as to optimize wireless performance of thewireless device 102.

For instance, the environment 100 depicts an internal view 116 thatrepresents a view of the wireless device 102 with a surface removed,such as a display screen of the wireless device 102. Depicted in theinternal view 116 is an antenna module 112 a, antenna module 112 b,antenna module 112 c, and antenna module 112 d, which representdifferent instances of the antenna modules 112. As shown, the antennamodules 112 a-112 d are each positioned at different physical locationson the wireless device 102. Further, the antenna modules 112 a-112 d areinterconnected to provide an integrated antenna structure for enablingthe wireless device to send and receive wireless signal. This particulararrangement of antenna modules 112 is presented for purpose of exampleonly, and it is to be appreciated that the described implementations canutilize a variety of different arrangements of antennas not expresslydescribed herein.

The wireless device 102 generates and/or maintains the device data 114,which is representative of various types of data that is used and/orobserved by the connectivity module 108. The device data 114, forinstance, includes attributes of wireless signal received and/ordetected by the connectivity module 108, such as base stationidentifiers, received signal strength indicator (RSSI), signal strength(e.g., in dBm), signal frequency band, signal quality (e.g.,signal-to-noise (S/N) ratio), and so forth. The device data 114 alsoincludes various device state information for the wireless device 102,such as described in more detail below.

In at least one implementation, the connectivity module 108 wirelesslyconnects the wireless device 102 to the wireless networks 104 viainteraction between the connectivity module 108 and network connectivitydevices 118. Generally, the network connectivity devices 118 arerepresentative of functionality to receive and transmit wireless signaland serve as access portals for the wireless networks 104. Examples ofthe network connectivity devices 118 include a wireless cellular basestation, a wireless access point (e.g., for a WLAN and/or a WirelessWide Area Network (WWAN)), a short-range wireless network access point,and so forth. In at least one implementation, the network connectivitydevice 118 and/or the wireless networks represent wireless signalsources for the wireless device 102.

The sensor system 110 is representative of functionality to detectvarious physical and/or logical phenomena in relation to the wirelessdevice 102, such as motion, light, image detection and recognition, timeand date, position, location, touch detection, temperature, and soforth. To enable the sensor system 110 to detect such phenomena, thesensor system 110 includes sensors 120 that are configured to generatesensor data 122. Examples of the sensors 120 include hardware and/orlogical sensors such as an accelerometer, a gyroscope, a camera, amicrophone, a clock, biometric sensors, touch input sensors, positionsensors, environmental sensors (e.g., for temperature, pressure,humidity, and so on), geographical location information sensors (e.g.,Global Positioning System (GPS) functionality), and so forth. In atleast some implementations, the sensor data 122 represents raw sensordata collected by the sensors 120. Alternatively or in addition, thesensor data 122 represents raw sensor data from the sensors 120 that isprocessed to generate processed sensor data, such as sensor data frommultiple sensors 120 that is combined to provide more complexrepresentations of wireless device 102 state than can be provided by asingle sensor 120.

The wireless device 102 further includes processes 124, examples ofwhich include applications 126 and system processes 128. Generally, theprocesses are representative of different tasks that can be executed viathe wireless device 102. For instance, the applications 126 representprograms that are executable via the wireless device 102 to performvarious tasks, such as web browsing, social media interaction, contentconsumption (e.g., video and/or audio streaming), online shopping,mobile payments, productivity tasks, and so forth. The system processes128 represent processes for performing various system-related tasks forthe wireless device 102, such as configuring various system settings ofthe wireless device. In at least one implementation, the systemprocesses 128 are hosted by an operating system of the wireless device102.

Further to techniques described herein, the device data 114 furtherincludes a state database 130, which stores various state informationgenerating as part of the calibration processes described herein. Forinstance, as detailed below, different state records can be generatedthat describe antenna states for the antenna modules 112 in differentusage scenarios. These antenna states can be stored in the statedatabase 130, and utilized to proactively configure the antenna modules112 based on various changes in device state, such as based on activityrelated to the processes 124.

The environment 100 further includes a connectivity service 132 which isconnected to and accessible via the wireless networks 104. The wirelessdevice 102, for instance, can interact with the connectivity service 132to obtain various connectivity-related information and services. Forexample, the connectivity service 132 includes service wireless data(“service data”) 134, which represents various wirelessconnectivity-related data obtained by the connectivity service 132 indifferent ways. The service data 134, for instance, can includeoverlapping and/or identical information to the device data 114. Furtherdetails concerning how the service data 134 is obtained and utilized arediscussed below.

FIGS. 2-9 depict different aspects of implementations for process basedantenna configuration. For instance, FIG. 2 depicts a scenario 200 forperforming aspects of a wireless calibration process for a wirelessdevice. In the scenario 200, a calibration event 202 occurs indicatingthat the wireless device 102 is to calibrate its wireless connectivity.According to various implementations, the connectivity module 108 candetect the calibration event 202 based on different detectedoccurrences. In this particular example, the calibration event 202 isbased on a process launch event 204 via which the connectivity module108 detects that a process 206 is launched. Generally, the process 206represents an implementation of a process 124. For instance, the launchevent 204 occurs based on the user 106 launching an instance of anapplication 126.

Based on the calibration event 202, the connectivity module 108initiates a calibration process 208 for calibrating wirelessconnectivity of the wireless device 102. As part of the calibrationprocess 208, the connectivity module 108 performs obstruction monitoring210. Generally, the obstruction monitoring 210 determines how a user isholding (e.g., grasping) the wireless device 102, such as based on aposition of a user's hand(s) relative to the wireless device 102. Thesensor system 110, for example, leverages the sensors 120 to detectwhich portions of the wireless device 102 are in contact with the user'shand and/or other object, such as a different portion of the user'sbody, a physical object other than the user (e.g., a phone holder,furniture, and so forth), and so on. In this way, the connectivitymodule 108 can receive obstruction position information from the sensorsystem 110 as part of the obstruction monitoring 210, and can correlatethe obstruction position information to different device states of thewireless device 102.

Optionally, the calibration process 208 includes antenna monitoring 212and process monitoring 214. The antenna monitoring 212, for instance,monitors wireless signal state at different instances of the antennamodules 112, such as different signal conditions of wireless signalreceived at instances of the antenna modules 112. Generally, wirelesssignal condition can include signal strength, signal quality, and soforth. The process monitoring 214 determines different states of theprocess 206, such as different execution states, differentfunctionalities accessed by the user, execution time of the process 206,and so forth.

Further to the scenario 200, results of the calibration process 208 arestored to the device data 114 as part of device states 216 that includedata describing different device states that occur in relation to (e.g.,during) the calibration process 208. In this example, the device states216 include user identifier (ID) 218, process identifier (ID) 220, andobstruction states 222. The user ID 218 identifies a user associatedwith the wireless device 102, such as a user that is authenticated withthe wireless device 102 during the calibration process, and/or a userthat is identified as interacting the with wireless device 102 duringthe calibration process. For instance, sensor data 122 from the sensorsystem 110 can be utilized to identify a particular user, such as basedon biometric attributes that are detected and correlated to the user ID218. The process ID 220 identifies a process 124 involved in thecalibration process 208, which in this example is the process 206.

The obstruction states 222 include results of the obstruction monitoring210, and generally describe different obstruction positions of thewireless device 102 that occurred as part of the calibration process208. The obstruction states 222, for example, can describe differentobstruction patterns (e.g., collections of points) on the wirelessdevice 102 that were in contact with a user as part of the calibrationprocess, time duration of each obstruction pattern, timestamps for eachobstruction pattern, and so forth.

Optionally, the device states 216 include antenna states 224 and processstates 226. The antenna states 224 describe different wireless signalconditions observed as part of the antenna monitoring 212, such assignal strength and/or signal quality observed at different pointsduring the calibration process 208. The process states 226 identifydifferent states of the process 206 that are identified as part of theprocess monitoring. For example, the process states 226 can identify atime of day at which the process 206 was launched, a duration ofexecution of the process 206 (e.g., a lapsed time between process launchand process termination), how frequently the user interacted with theprocess, which functionality of the process was accessed, and so forth.

In at least some implementations, the various states described in thedevice states 216 can be correlated with one another to indicaterelationships between the different states. For instance, a change in aprocess state 226 may be correlated with a change in an obstructionstate 222, or vice-versa. This is presented as but one example, and itis to be appreciated that various interrelationships between thedifferent states can be identified and utilized further to thetechniques described herein.

In at least some implementations, the calibration process 208 mayiterate for a period of time and may terminate based on an occurrence ofa termination event, such as a calibration timer elapsing, terminationof the process 206, the connectivity module 108 determining that athreshold number of data points (e.g., different device states 216) havebeen collected, the connectivity module 108 determining that aobstruction position of the wireless device 102 has not changed for athreshold period of time, and so forth. Thus, the device states 216 maybe dynamically updated during the calibration process to provide arobust data set that is stored and used for optimizing wirelessperformance of the wireless device 102 in different scenarios. Considernow a discussion of some example device states.

FIG. 3 depicts a scenario 300 for identifying different device statesfor calibrating the wireless device 102. In the scenario 300, a userinteracts with the wireless device 102 while the calibration process 208is active. The user, for instance, launches the process 206, whichgenerates a calibration event 202 to initiate the calibration process208. The user interacts with the process 206 via the wireless device102, such as by providing input to the wireless device 102 to accessfunctionality of the process 206. Further, during interaction with theprocess 206, the user holds the wireless device 102 with a grip 302 oftheir hand 304.

Accordingly, the connectivity module 108 performs the various statemonitoring described above. For instance, the obstruction monitoring 210identifies portions of the wireless device 102 that are occluded by(e.g., in contact with and/or in proximity to) the grip 302. The sensorsystem 110, for example, utilizes the sensors 120 to identify whichregions of the wireless device 102 are occluded by the user's hand 304.Generally, this can involve various types of sensors 120, such as acapacitive sensor, pressure sensor, a temperature sensor, an opticalsensor, and so forth. Accordingly, the sensor system detects that thegrip 302 occludes regions 306 a, 306 b, and 306 c of the wireless device102. The occluded regions 306 a, 306 b, for instance, are on a frontsurface and/or side edge of the wireless device 102, and the occludedregion 306 c is on a rear surface of the wireless device 102. Forexample, the occluded region 306 a represents a portion of the wirelessdevice 102 occluded by the user's fingertips, the occluded region 306 bis occluded by the user's thumb, and the occluded region 306 c isoccluded by the palm of the user's hand 304. These are presented forpurpose of example only, and it is to be appreciated that variousobjects may be detected as occluding portions of the wireless device102, such as a user's face (e.g., in a phone call scenario), an externalobject such as a desk, a phone holder (e.g., in a vehicle), and soforth.

FIG. 4 depicts a scenario 400 for generating an occlusion pattern aspart of a calibration process. The scenario 400, for instance, isperformed in conjunction with the scenario 300 and as part of thecalibration process 208. In the scenario 400, based on identification ofthe occluded regions 306 a-306 c, an occlusion pattern 402 is generated.Generally the occlusion pattern 402 includes a front pattern 404 and arear pattern 406, which include a front mapping 408 and a rear mapping410 of the wireless device 102, respective. The front mapping 408 is adata representation of a front surface of the wireless device 102, suchas a coordinate map that describes the physical bounds of the frontsurface. Further, the rear mapping 410 is a data representation of arear surface of the wireless device 102, such as a coordinate map thatdescribes the physical bounds of the rear surface.

The front pattern 404 identifies the occluded regions 306 a, 306 brelative to the front mapping 408, and the rear mapping identifies theoccluded region 306 c relative to the rear mapping 410. Further, and asdepicted in the scenario 400, the front mapping 408 and the rear mapping410 describe relative positions of the antenna modules 112 a-112 d onthe wireless device 102. In this way, the occlusion pattern 402 canindicate whether any of the antenna modules are occluded, and a relativeamount of occlusion. In this example, the front pattern indicates thatthe antenna module 112 d is likely occluded by the occluded region 306a. Further, the antenna module 112 c may be partially or fully occludedby the occluded region 306 c. The antenna modules 112 b, 112 d may bepartially occluded by the occluded region 306 c, and the antenna module112 a may be free from obstruction, e.g., non-occluded.

Thus, the occlusion pattern 402 describes different physical regions ofthe wireless device 102 and antenna modules 112 that are occluded by thegrip 302, and antenna modules 112 that are likely occluded, partiallyoccluded, or non-occluded. The occlusion pattern 402 is accordinglyidentified as an obstruction state 412 of the wireless device as part ofthe calibration process 208, which represents an example implementationof the obstruction states 222.

FIG. 5 depicts a scenario 500 for determining antenna state as part of acalibration process. The scenario 500, for instance, is optionallyperformed in conjunction with the scenarios 300, 400 and as part of thecalibration process 208. In the scenario 500, antenna state of thedifferent antenna modules 112 is determined, such as part of the antennamonitoring 212. The connectivity module 108, for instance, monitorswireless signal condition at each of the antenna modules 112. Theconnectivity module 108 then defines the antenna states 502 based onsignal condition observed at each of the antenna modules 112. Theconnectivity module 108, for example, defines a separate antenna state502 a-502 d for each of the antenna modules 112, and each antenna state502 a-502 d describes wireless signal condition observed at each of theantenna modules 112 as part of the calibration process 208.

Generally, an antenna state 502 at a particular antenna module 112 candescribe wireless signal condition in various ways. For instance,wireless signal condition can be described quantitatively across thecalibration process 208, such as wireless signal strength (e.g., RSSI,dBm) and/or wireless signal quality (e.g., S/N ratio) observed atvarious time steps during the calibration process 208. Additionally oralternatively, wireless signal condition can be described qualitatively,such as by comparing observed signal condition to a signal thresholdthat is defined based on signal strength and/or signal quality. Forinstance, an antenna state 502 for an antenna module 112 that meets thesignal threshold for the calibration process 208 can be indicated as“good,” wherein as an antenna state for an antenna module 112 that isbelow the signal threshold can be indicated as “poor.” In at least oneimplementation, observed wireless signal condition of an antenna module112 can be averaged over the time span of the calibration process 208 todefine the antenna module's overall antenna state 502 for thecalibration process. Thus, the antenna state 502 describes wirelesssignal condition observed at each antenna module 112 over thecalibration process 208.

For example, with the wireless device 102 held in the grip 302, theantenna module 112 a may be free of occlusion and thus may exhibit goodwireless performance. Thus, the antenna state 502 a may indicate a goodwireless condition. However, in the grip 302, the antenna module 112 dmay be occluded by the user's thumb and thus may exhibit poor wirelessperformance. Accordingly, this performance attribute of the antennamodule 112 d may be reflected in the antenna state 502 d.

In conjunction with the obstruction monitoring 210 and the antennamonitoring described above, the process monitoring 214 may also beperformed to generate process state 504. Accordingly this various stateinformation combines to provide an overall indication of the devicestates 216 for the wireless device 102 that occur as part of (e.g.,during) the calibration process 208.

In some scenarios, during a calibration process, a user may switch theirgrip on a device being calibrated. For instance, FIG. 6 depicts ascenario 600 for detecting a grip change during a calibration process.The scenario 600, for instance, represents a continuation of thescenarios 300-500, and may occur while the calibration process 208described in those scenarios is still active. In the scenario 600, theuser switches from the grip 302 to a grip 602 of the wireless device 102while the process 206 remains active. As illustrated, the grip 602involves the user grasping the wireless device 102 with two hands 304 a,304 b. Accordingly, the sensor system 110 identifies regions of thewireless device 102 that are occluded by the grip 602 of the user'shands 304 a, 304 b. The sensor system 110, for instance, detectsoccluded regions 604 a, 604 b on the front surface of the wirelessdevice 102, and occluded regions 604 c, 604 d on the rear surface of thewireless device 102. The sensor system 110 notifies the connectivitymodule 108 of the occluded regions 604 a-604 d, such as via a pushand/or pull notification. Accordingly, the connectivity module 108generates an occlusion pattern 606 that describes the occluded regions604 a-604 d relative to the wireless device 102, e.g., front and rearsurfaces of the wireless device 102. Further, the occlusion pattern 606may also indicate whether any of the antenna modules 112 are likelyoccluded and if so, which antenna modules. Generally, the occlusionpattern 606 may be generated and implemented similarly to the occlusionpattern 402, discussed above.

FIG. 7 depicts a scenario 700 for incorporating a change in obstructionstate into a calibration process. The scenario 700, for instance,represents a continuation of the scenarios 300-700. In the scenario 700,the connectivity module 108 identifies the occlusion pattern 606 as anobstruction state 702 of the wireless device 102 as part of thecalibration process 208. Optionally, the connectivity module 108performs further antenna monitoring 212 to ascertain antenna state 704of the antenna modules 112 while the wireless device 102 is held via thegrip 602, e.g., the obstruction state 702. The antenna state 704, forinstance, describes wireless signal conditions at the individual antennamodules 112. For instance, the change from the grip 302 to the grip 602may alter performance characteristics of an antenna module 112. Anantenna module 112 that was previously occluded by the grip 302 (e.g.,the antenna module 112 d) may no longer be occluded by the grip 602, andthus may exhibit a better wireless signal condition in the grip 302.Further, an antenna module 112 that previously exhibited good wirelesssignal condition in the grip 302 (e.g., the antenna module 112 a) maynow be occluded by the grip 602, and thus may exhibit decreased (e.g.poor) wireless signal condition. In at least some implementations,process monitoring 214 may be performed to ascertain a process state 706while the wireless device 102 is held via the grip 602.

While the example obstruction states presented above are discussed inthe context of a user gripping the wireless device 102, it is to beappreciated that the described techniques may also be employed to detecta wide variety of other obstruction states and to perform antennaconfiguration for the different obstruction states, such as when awireless device is placed on a user's lap, when a wireless device isplaced into a phone holder (e.g., for hands free operation in avehicle), when a wireless device is placed on a piece of furniture(e.g., on a desk), and so forth.

FIG. 8 depicts a scenario 800 for generating a representation of devicestate ascertained as part of a calibration process. The scenario 800,for instance, occurs in conjunction with the scenarios 300-800. In thescenario 800, the connectivity module 108 aggregates the various stateinformation generated as part of the monitoring activities describedabove into a device state 802, which is based on the user ID 218 and theprocess ID 220 involved in the calibration process 208 described above.Further, the device state 802 includes different state records 804 thatare based on different states observed as part of the calibrationprocess 208. A state record 804 a, for instance, is based on theobstruction state 412, and includes the antenna state 502 and theprocess state 504. Further, a state record 804 b is based on theobstruction state 702, and includes the antenna state 704 and theprocess state 706. While two different state records 804 are depicted inthe scenario 800, it is to be appreciated that any number of staterecords may occur during a calibration process, such as more or lessthan two.

Each of the state records 804 include a respective state duration 806,which represents a time value indicating how long each state record 804occurred as part of the calibration process 208. For instance, a stateduring 806 a of the state record 804 a indicates a duration of time thatthe obstruction state 412 occurred as part of the calibration process,and a state duration 806 b indicates a duration of time that theobstruction state 702 occurred as part of the calibration process. Thestate durations 806 a, 806 b, for example, indicate durations of timethe user grasped the wireless device 102 via the grips 302, 602,respectively. In an implementation where a user changes grip multipletimes over a calibration process 208 such that a particular instance ofa obstruction state occurs multiple different times over the calibrationprocess, a state duration 806 for the obstruction state can bedetermined as a cumulative total time duration that the obstructionstate occurred as part of the calibration process.

Each of the state records 804 further includes a confidence score 808,which indicates a confidence that a respective state record 804 is aprimary interaction, e.g., for the user ID 218 and the process ID 220.In at least one implementation, a confidence score 808 for a particularstate record 804 is calculated based on a respective state duration 806.For instance, consider a first scenario where the calibration process208 proceeds for a calibration period of 5 minutes. Further, the stateduration 806 a for the state record 804 a over the calibration period is30 seconds, and the state duration 806 b for the state record 804 b is 4minutes, 30 seconds. Accordingly, the confidence score 808 b for thestate record 804 b may be high (e.g., 0.9), whereas the confidence score808 a for the state record 804 a may be lower, e.g., 0.1. In at leastone implementation, this indicates that the state record 804 b is aprimary interaction state.

Consider another example where, for a same duration of calibrationperiod, the state duration 806 a for the state record 804 a over thecalibration period is 2 minutes, 20 seconds, and the state duration 806b for the state record 804 b is 2 minutes, 40 seconds. Accordingly, theconfidence scores 808 a, 808 b may be similar and may be low, e.g., 0.54and 0.56, respectively. Since the confidence scores 808 a, 808 b are lowand/or are similar, neither state record 804 a, 804 b may be identifiedas a primary interaction state.

In an implementation where a confidence score 808 for a particular staterecord 804 exceeds a threshold confidence score, and/or where theconfidence score 808 exceeds a threshold difference between confidencescores for other state records 804, the particular state record 804 canbe designated by the connectivity module 108 as a primary interactionstate 810. The primary interaction state 808, for instance, is based ona state record 804 that occurs most frequently for the user ID 218 andthe process ID 220.

FIG. 9 depicts an example implementation of the state database 130,which stores different device states 216 including the device state 802detailed above. Generally, each device state 130 corresponds to adifferent instance of a process ID 220 and/or a user ID 218, and thuscan be used to configure wireless connectivity of a device based onmatching a current user ID and/or process ID of the device to acorresponding device state 216. For instance, based on a matching devicestate 216, antenna state information from the device state can beutilized to determine which antenna(s) to activate or deactivate, andwhich antenna(s) to optimize. Further, the state database 130 isportable and can be shared between different devices to enable wirelessperformance optimization across the different devices. For instance,when the calibration process 208 is performed on the wireless device 102to generate device state(s) 216 for the state database 130, thegenerated device state(s) can be shared to the connectivity service 132and saved to the service data 134. The connectivity service 132 can makethe device state(s) 216 available to other devices, such as in responseto a request from a different device for device state information.Alternatively or in addition, the wireless device 102 can directly sharethe device state information, such as via direct device-to-devicecommunication with another wireless device.

FIG. 10 depicts a method 1000 for calibrating wireless performance of awireless device. At 1002, a calibration event pertaining to a wirelessdevice is detected indicating that a wireless device is to be calibratedfor wireless connectivity and based on a process that is active on thewireless device. The connectivity module 108, for instance, detects thata process 124 is launched on the wireless device, such as based on auser initiating an application 126 or a system process 128. Accordingly,the calibration process 208 is initiated.

At 1004, obstruction states are identified that each identify regions ofthe wireless device that are occluded in a respective obstruction state.For example, the sensor system 110 detects regions of the wirelessdevice 102 that are occluded in each obstruction state, such as regionsin contact with and/or obstructed by a user's grasp of the wirelessdevice 102. As described above, an obstruction state can correspond toan identified occlusion pattern that describes regions of a device thatare occluded in the obstruction state.

At 1006, for each of the obstruction states, a performance parameter isdetermined for each antenna of a set of antennas of the wireless device.Each performance parameter, for instance, is based on whether arespective antenna is at least partially occluded in a respectiveobstruction state. For each obstruction state, for instance, theconnectivity module 108 maps occluded portions of the wireless device102 to known locations for the antenna modules 112 to ascertain whichantenna modules are likely occluded. A performance parameter can bespecified in various ways, such as whether a respective antenna module112 is partially or completely occluded, or is not occluded, e.g., isfree of obstruction. Alternatively or in addition, a performanceparameter can be specified as an antenna quality descriptor thatdescribes an estimated signal quality of a respective antenna module112. For instance, if a particular antenna module 112 is determined tobe occluded in an obstruction state, a performance parameter for theparticular antenna module can be specified as “poor.” If a particularantenna module 112 is determined to be partially occluded, a performanceparameter can be specified as “fair.” Further, if a particular antennamodule 112 is determined to be free from occlusion (e.g., notobstructed), a performance parameter can be specified as “good.”Generally, an antenna module 112 that identified as “poor” is expectedto provide low quality wireless communication, whereas an antenna module112 identified as “good” is expected to provide good quality wirelesscommunication.

At 1008, a state record is generated that identifies the process, theantennas, and respective performance parameters for the antennas. Forexample, the connectivity module 108 generates a state record 804 thatincludes a process ID for the process, identifiers for individualantennas of the set of antenna modules 112, and a performance parameterfor each antenna module. In at least one implementation, the staterecord 804 also includes a user ID 218 for a user involved in thecalibration process.

As mentioned above, multiple state records 804 may be generated as partof a calibration process 208, such as when a user switches a grip of thewireless device 102 during the calibration process. Accordingly, eachstate record can be assigned a confidence score that indicates arelative confidence that a respective state record represents a primaryinteraction state for the wireless device 102. As discussed above, aconfidence score for a state record may be calculated based on a timeduration of an obstruction state associated with the state record, e.g.,interaction state. In at least one implementation, a state record 804with a highest confidence score is designated as a primary state recordfor the process, and for a particular user ID 218 that interacts withthe process.

At 1010, the state record is caused to be available for configuring theset of antennas of the wireless device. The connectivity module 108, forinstance, stores a state record 804 in the state database 130 for use inconfiguring the antenna modules 112 for wireless communication, such aswhen the process 124 identified by the state record 804 is subsequentlylaunched on the wireless device 102. Generally, the state database 130stores multiple different instances of state records that are associatedwith a different process but that may each be associated with a commonuser ID 218 such that the state records describe how an individual userinteracts with different instances of processes 124. Further, the statedatabase 130 may store device states 216 across multiple different userIDs 218 such that ways in which different users interact with differentprocesses can be identified as utilized to configure operation ofantenna modules 112 based on which user is currently involved, and whichprocess is currently active.

FIG. 11 depicts a method 1100 for configuring antennas of a wirelessdevice. At 1102, based on a process that is active on a wireless device,an optimization event is detected indicating that a set of antennas ofthe wireless device are to be optimized for wireless communication. Theconnectivity module 108, for instance, detects that an instance of aprocess 124 is launched on the wireless device 102, and/or that wirelessconnectivity of the wireless device 102 is to be optimized based on aprocess that is active on the wireless device 102. Generally, an“active” process may refer to a process that is scheduled to beexecuted, a process that is initializing execution, and/or a processthat is currently executing, e.g., has at least one active thread on thewireless device 102.

At 1104, a state record is accessed that identifies the process and thatspecifies a performance parameter for each antenna. For example, theconnectivity module 108 searches the state database 130 using a processID 220 for the process to identify a state record 804 that includes theprocess ID 220. In at least one implementation, in addition to theprocess ID 220, the connectivity module 108 may also search using a userID 218, such as for a user associated with the wireless device 102. Astate record is identified that corresponds to the process ID and/or theuser ID, and antenna performance parameters are identified from thestate record.

At 1106, an antenna is configured based on a respective performanceparameter. For instance an antenna is activated based on its respectiveperformance parameter, or an antenna is deactivated based on itsrespective performance parameter. Consider, for instance, that aperformance parameter for a particular antenna module 112 indicates thatthe antenna module is “good” according to the current state record.Accordingly, the particular antenna module 112 can be activated. If thatparticular antenna module is determined to be already active, theantenna module is left active. Consider another example where aperformance parameter for a particular antenna module 112 indicates thatthe antenna module is “poor” according to the identified state record.Accordingly, the particular antenna module can be deactivated, e.g.,turned off or left inactive if already inactive. For a set of multipleantenna modules 112, each antenna module can be configured based on itsrespective performance parameter.

FIG. 12 depicts a method 1200 for configuring antennas of a wirelessdevice. At 1202, an indication is received that antennas of a wirelessdevice are to be optimized based on a process. The connectivity module108, for instance, determines that a process 124 is active on thewireless device 102, such as based on a process launch event or otherindication of a process. In at least one implementation, antennaoptimization may occur as a background process while the subject processis executing. Generally, this may occur to refresh optimization valuesin the state database 130 from time-to-time to account for possible userbehavior changes (e.g., if a user adopts a different way of grasping thewireless device 102), and/or if the confidence scores are not highenough to make a decision on antenna configuration.

At 1204, it is determined whether a state record for the process isavailable. For example, the connectivity module 108 searches the statedatabase 130 for a state record 804 using a process ID 220 for theprocess, and/or a user ID 218 for a user associated with the wirelessdevice 102. If a state record for the process is not available (“No”),at 1206 a calibration process is implemented to calibrate antennas ofthe wireless device based on the process. The calibration processesdescribed above, for instance, are performed, such as described withreference to the method 1000.

If a state record for the process is available, at 1208 it is determinedif a confidence score for the state record meets a threshold confidencevalue. The connectivity module 108, for instance, compares a confidencescore for an identified state record to a threshold confidence value.The threshold confidence value, for instance, is predefined prior toinitiating device calibration and/or antenna optimization. Differentways for generating confidence scores are described above. If theconfidence score for the state record meets the threshold confidencevalue (“Yes”), at 1210 antennas of the wireless device are configuredbased on performance parameters specified by the state record. Theconnectivity module 108, for instance, identifies a performanceparameter in the state record, and configures an antenna module 112based on the performance parameter. As described above, for instance,the connectivity module 108 can activate or deactivate an antenna module112 based on whether a respective performance parameter indicates thatthat the antenna module has a “poor” estimated signal condition, or a“good” or “fair” estimated signal condition. In at least oneimplementation, step 1210 implements the method 1100 for configuring aset of antennas of a wireless device using information in the staterecord.

If the confidence score for the state record does not meet the thresholdconfidence value (“No”), the method proceeds to 1206 where a calibrationprocess is implemented to calibrate antennas of the wireless devicebased on the process. In at least one implementation, this represents arecalibration of the wireless device for the process, such as where aprevious calibration process did not result in a state record with asufficient reliable confidence value. Based on the calibration process,a new state record is generated for the process, or a previouslygenerated state record with a low confidence score is updated. The staterecord may then be utilized to configure antennas of the wirelessdevice, such as described above.

FIG. 13 depicts a method 1300 for configuring antennas of a wirelessdevice. At 1302, an indication is received to optimize antennas of awireless device for a process. The connectivity module 108, forinstance, detects an optimization event, such as based on launch of aprocess 124 on the wireless device 102. At 1304, it is determinedwhether a state record associated with the process identifies an antennathat meets a performance parameter threshold. For example, theconnectivity module 108 locates a state record 804 that correlates withthe process (e.g., based on a matching process ID 220), and determineswhether the state record identifies any antennas that meet a performanceparameter threshold. For instance, a performance parameter threshold canbe defined as antennas that are identified as “good” or “fair,” such asbased on the calibration processes described above. Alternatively or inaddition, a performance parameter threshold can be defined based onrelative occlusion of antennas based on an obstruction state, such asantennas that are free from occlusion or only partially occluded.

If the state record does not identify an antenna that meets theperformance parameter threshold (“No”), at 1306 the optimization processterminates. In at least one implementation, based on termination of theoptimization process, a default device behavior can be implemented foradapting antenna performance, such as a reactive behavior that monitorswireless performance of antennas and adapts antennas to compensate forobserved changes in antenna performance. Alternatively or additionally,a recalibration process can be performed, such as described above.

If the state record identifies an antenna that meets the performanceparameter threshold (“Yes”), at 1308 the identified antenna is caused tobe active. Generally, this includes activating the antenna module 112 ifthe antenna module is not currently active, or maintaining the antennamodule as active if its already active.

At 1310, it is determined whether the state record identifies an antennathat is below the performance parameter threshold. The connectivitymodule 108, for instance, determines whether the identified state record804 identifies an antenna with a performance parameter below thethreshold, such as an antenna that is indicated as having a poorestimated signal condition, and/or an antenna that is identified asbeing occluded. If the state record does not identify an antenna that isbelow the performance parameter threshold (“No”), the method proceeds to1306 where the optimization process terminates.

If the state record identifies an antenna that is below the performanceparameter threshold (“Yes”), at 1312 it is determined whether a currentsignal condition of the antenna meets a signal condition threshold.Generally, a signal condition threshold can be defined in various ways,such as a threshold signal strength, a threshold signal quality, and soforth. Accordingly, the connectivity module 108 can determine a currentsignal condition of the antenna module 112, (e.g., current signalstrength, signal quality, and so forth) and compare the current signalcondition to the signal condition threshold. If the current signalcondition of the antenna meets the signal condition threshold (“Yes”),at 1314 the antenna is maintained in an active state. For instance, ifthe identified antenna module 112 is active, it is maintained in anactive state. The method may then proceed to 1306 where the optimizationprocess terminates.

If the current signal condition of the antenna does not meet the signalcondition threshold (“No”), at 1316 the antenna is maintained in aninactive state. For instance, if the identified antenna module 112 isactive, it is deactivated. The method may then proceed to 1306 where theoptimization process terminates.

Thus, implementations of process based antenna configuration includeways for utilizing different usage states (e.g., device obstructionstate) to make decisions regarding wireless connectivity.

The example methods described above may be performed in various ways,such as for implementing different aspects of the systems and scenariosdescribed herein. Generally, any services, components, modules, methods,and/or operations described herein can be implemented using software,firmware, hardware (e.g., fixed logic circuitry), manual processing, orany combination thereof. Some operations of the example methods may bedescribed in the general context of executable instructions stored oncomputer-readable storage memory that is local and/or remote to acomputer processing system, and implementations can include softwareapplications, programs, functions, and the like. Alternatively or inaddition, any of the functionality described herein can be performed, atleast in part, by one or more hardware logic components, such as, andwithout limitation, Field-programmable Gate Arrays (FPGAs),Application-specific Integrated Circuits (ASICs), Application-specificStandard Products (ASSPs), System-on-a-chip systems (SoCs), ComplexProgrammable Logic Devices (CPLDs), and the like. The order in which themethods are described is not intended to be construed as a limitation,and any number or combination of the described method operations can beperformed in any order to perform a method, or an alternate method.

FIG. 14 illustrates various components of an example device 1400 inwhich aspects of process based antenna configuration can be implemented.The example device 1400 can be implemented as any of the devicesdescribed with reference to the previous FIGS. 1-13, such as any type ofwireless device, mobile phone, mobile device, wearable device, tablet,computing, communication, entertainment, gaming, media playback, and/orother type of electronic device. For example, the wireless device 102 asshown and described with reference to FIGS. 1-13 may be implemented asthe example device 1400. In a wearable device implementation, the devicemay include any one or combination of a watch, armband, wristband,bracelet, glove or pair of gloves, glasses, jewelry items, clothingitems, any type of footwear or headwear, and/or other types ofwearables.

The device 1400 includes communication transceivers 1402 that enablewired and/or wireless communication of data 1404 with other devices. Thedata 1404 can include any of device identifying data, device locationdata, wireless connectivity data, and wireless protocol data.Additionally, the data 1404 can include any type of audio, video, and/orimage data. Example communication transceivers 1402 include wirelesspersonal area network (WPAN) radios compliant with various IEEE 1402.15(Bluetooth™) standards, wireless local area network (WLAN) radioscompliant with any of the various IEEE 1402.11 (Wi-Fi™) standards,wireless wide area network (WWAN) radios for cellular phonecommunication, wireless metropolitan area network (WMAN) radioscompliant with various IEEE 1402.16 (WiMAX™) standards, and wired localarea network (LAN) Ethernet transceivers for network data communication.

The device 1400 may also include one or more data input ports 1406 viawhich any type of data, media content, and/or inputs can be received,such as user-selectable inputs to the device, messages, music,television content, recorded content, and any other type of audio,video, and/or image data received from any content and/or data source.The data input ports may include USB ports, coaxial cable ports, andother serial or parallel connectors (including internal connectors) forflash memory, DVDs, CDs, and the like. These data input ports may beused to couple the device to any type of components, peripherals, oraccessories such as microphones and/or cameras.

The device 1400 includes a processing system 1408 of one or moreprocessors (e.g., any of microprocessors, controllers, and the like)and/or a processor and memory system implemented as a system-on-chip(SoC) that processes computer-executable instructions. The processorsystem may be implemented at least partially in hardware, which caninclude components of an integrated circuit or on-chip system, anapplication-specific integrated circuit (ASIC), a field-programmablegate array (FPGA), a complex programmable logic device (CPLD), and otherimplementations in silicon and/or other hardware. Alternatively or inaddition, the device can be implemented with any one or combination ofsoftware, hardware, firmware, or fixed logic circuitry that isimplemented in connection with processing and control circuits, whichare generally identified at 1410. The device 1400 may further includeany type of a system bus or other data and command transfer system thatcouples the various components within the device. A system bus caninclude any one or combination of different bus structures andarchitectures, as well as control and data lines.

The device 1400 also includes computer-readable storage memory 1412(e.g., memory devices) that enable data storage, such as data storagedevices that can be accessed by a computing device, and that providepersistent storage of data and executable instructions (e.g., softwareapplications, programs, functions, and the like). Examples of thecomputer-readable storage memory 1412 include volatile memory andnon-volatile memory, fixed and removable media devices, and any suitablememory device or electronic data storage that maintains data forcomputing device access. The computer-readable storage memory caninclude various implementations of random access memory (RAM), read-onlymemory (ROM), flash memory, and other types of storage media in variousmemory device configurations. The device 1400 may also include a massstorage media device.

The computer-readable storage memory 1412 provides data storagemechanisms to store the data 1404, other types of information and/ordata, and various device applications 1414 (e.g., softwareapplications). For example, an operating system 1416 can be maintainedas software instructions with a memory device and executed by theprocessing system 1408. The device applications may also include adevice manager, such as any form of a control application, softwareapplication, signal-processing and control module, code that is nativeto a particular device, a hardware abstraction layer for a particulardevice, and so on. Computer-readable storage memory 1412 representsmedia and/or devices that enable persistent and/or non-transitorystorage of information in contrast to mere signal transmission, carrierwaves, or signals per se. Computer-readable storage memory 1412 do notinclude signals per se or transitory signals.

In this example, the device 1400 includes a connectivity module 1418that implements aspects of process based antenna configuration, and maybe implemented with hardware components and/or in software as one of thedevice applications 1414, such as when the device 1400 is implemented asthe wireless device 102. An example, the connectivity module 1418 can beimplemented as the connectivity module 108 described in detail above. Inimplementations, the connectivity module 1418 may include independentprocessing, memory, and logic components as a computing and/orelectronic device integrated with the device 1400. The device 1400 alsoincludes device data 1420 for implementing aspects of process basedantenna configuration, and may include data from the connectivity module108.

In this example, the example device 1400 also includes a camera 1422 andmotion sensors 1424, such as may be implemented in an inertialmeasurement unit (IMU). The motion sensors 1424 can be implemented withvarious sensors, such as a gyroscope, an accelerometer, and/or othertypes of motion sensors to sense motion of the device. The variousmotion sensors 1424 may also be implemented as components of an inertialmeasurement unit in the device.

The device 1400 also includes a wireless module 1426, which isrepresentative of functionality to perform various wirelesscommunication tasks. For instance, for the wireless device 102, thewireless module 1426 can be leveraged to scan for and detect wirelessnetworks, as well as negotiate wireless connectivity to wirelessnetworks for the wireless device 102. The device 1400 can also includeone or more power sources 1428, such as when the device is implementedas a wireless device. The power sources 1428 may include a chargingand/or power system, and can be implemented as a flexible strip battery,a rechargeable battery, a charged super-capacitor, and/or any other typeof active or passive power source. Generally, utilizing implementationsof process based antenna configuration enables the power sources 1428 tobe conserved as part of a wireless network connectivity process.

The device 1400 also includes an audio and/or video processing system1430 that generates audio data for an audio system 1732 and/or generatesdisplay data for a display system 1434. The audio system and/or thedisplay system may include any devices that process, display, and/orotherwise render audio, video, display, and/or image data. Display dataand audio signals can be communicated to an audio component and/or to adisplay component via an RF (radio frequency) link, S-video link, HDMI(high-definition multimedia interface), composite video link, componentvideo link, DVI (digital video interface), analog audio connection, orother similar communication link, such as media data port 836. Inimplementations, the audio system and/or the display system areintegrated components of the example device. Alternatively, the audiosystem and/or the display system are external, peripheral components tothe example device.

Although implementations of process based antenna configuration havebeen described in language specific to features and/or methods, thesubject of the appended claims is not necessarily limited to thespecific features or methods described. Rather, the features and methodsare disclosed as example implementations of process based antennaconfiguration, and other equivalent features and methods are intended tobe within the scope of the appended claims. Further, various differentexamples are described and it is to be appreciated that each describedexample can be implemented independently or in connection with one ormore other described examples. Additional aspects of the techniques,features, and/or methods discussed herein relate to one or more of thefollowing:

A method, comprising: detecting a calibration event indicating that awireless device is to be calibrated for wireless connectivity and basedon a process that resides on the wireless device; initiating calibrationbased on the calibration event, the calibration including: identifyingone or more obstruction states that each identify one or more regions ofthe wireless device that are occluded in a respective obstruction state;determining, for each of the one or more obstruction states, aperformance parameter for each antenna of a set of antennas of thewireless device, each performance parameter being based on whether arespective antenna is at least partially occluded in a respectiveobstruction state; generating a state record identifying the process,one or more of the antennas, and respective performance parameters forthe one or more of the antennas; and causing the state record to beavailable for configuring the set of antennas of the wireless device.

Alternatively or in addition to the above described method, any one orcombination of: wherein the calibration event is triggered based ondetecting one or more of that the process is launched or that theprocess is active on the wireless device; wherein the process comprisesone or more of an application or a system process of the wirelessdevice; wherein said identifying the one or more obstruction states isbased on sensor data indicating one or more regions of the wirelessdevice that are one or more of in contact with a user or in proximity toa user; wherein a performance parameter for a particular antenna for aparticular obstruction state indicates an estimated signal condition forthe antenna in the particular obstruction state; wherein a performanceparameter for a particular antenna for a particular obstruction stateindicates an estimated signal condition for the antenna in theparticular obstruction state, and wherein the signal condition isestimated based on whether the particular antenna is at least partiallyoccluded in the particular obstruction state; wherein said identifyingthe one or more obstruction states comprises identifying multipleobstruction states as part of the calibration, the method furthercomprising: generating, for each obstruction state, a confidence scoreindicating a confidence that the obstruction state is a primaryinteraction state for the process on the wireless device; wherein saidgenerating a confidence score for each obstruction state is based on arespective time duration for each obstruction state; further comprisingselecting a obstruction state with a highest confidence score, whereinsaid generating the state record comprises including, in the staterecord, performance parameters for the one or more of the antennasobserved in conjunction with the obstruction state with the highestconfidence score; wherein said generating the state record furthercomprises including a user identifier for a user associated with thewireless device.

A method comprising: detecting, based on a process that resides on awireless device, an optimization event indicating that a set of antennasof the wireless device are to be optimized for wireless communication;accessing a state record that identifies the process and that specifiesa performance parameter for each antenna; and configuring one or more ofthe antennas based on the performance parameter, including at least oneof activating an antenna based on its respective performance parameter,or deactivating an antenna based on its respective performanceparameter.

Alternatively or in addition to the above described method, any one orcombination of: wherein said detecting the optimization event is basedon an indication that the process is launched on the wireless device,the process comprising one or more of an application or a systemprocess; wherein said accessing the state record comprises: searching adatabase of state records utilizing an identifier for the process;identifying the state record based on the state record including theidentifier for the process; and selecting the state record based on aconfidence score for the state record meeting a confidence threshold;wherein the state record indicates a poor estimated signal condition fora particular antenna, and wherein the method further comprises:measuring a current signal condition of the particular antenna; anddetermining whether to disable the particular antenna based on thecurrent signal condition; further comprising: disabling the particularantenna if the current signal condition indicates a poor signalcondition; or maintaining the particular antenna as active if thecurrent signal condition indicates a good signal condition; wherein saidconfiguring the one or more antennas is performed independent of acurrent observation of a signal condition of the one or more antennas;wherein the state record is generated based on a calibration processperformed on a different device.

A wireless device comprising: a sensor system; a set of antennas; and aconnectivity module implemented to: receive data from the sensor systemdescribing an obstruction state that identifies one or more regions ofthe wireless device that are occluded while a particular process isactive on the wireless device; determine for the obstruction state aperformance parameter for each antenna of the set of antennas, eachperformance parameter being based on whether a respective antenna is atleast partially occluded in the obstruction state; detecting a launchevent indicating that the process is launched on the wireless device;and configuring, based on the launch event, one or more of the antennasbased on a respective performance parameter for the one or moreantennas.

Alternatively or in addition to the above described wireless device, anyone or combination of: wherein the data from the sensor systemidentifies multiple obstruction states, and wherein the connectivitymodule is further implemented to: calculate a confidence score for eachobstruction state, wherein each confidence score is indicative of aconfidence that a respective obstruction state represents a primaryinteraction state for the particular process; and select the obstructionstate based on its confidence score; wherein the data from the sensorsystem identifies multiple obstruction states, and wherein theconnectivity module is further implemented to: calculate a confidencescore for each obstruction state, wherein each confidence score isindicative of a confidence that a respective obstruction staterepresents a primary interaction state for the particular process;compare each confidence score to a confidence score threshold; andinitiate recalibration of the wireless device based on each confidencescore being below the confidence score threshold.

1. A method comprising: detecting, based on a process that resides on awireless device, an optimization event indicating that a set of antennasof the wireless device are to be optimized for wireless communication;accessing a state record that identifies the process and that specifiesa performance parameter for each antenna; and configuring one or more ofthe antennas based on the performance parameter, including at least oneof activating an antenna based on its respective performance parameter,or deactivating an antenna based on its respective performanceparameter.
 2. The method as recited in claim 1, wherein said detectingthe optimization event is based on an indication that the process islaunched on the wireless device, the process comprising one or more ofan application or a system process.
 3. The method as recited in claim 1,wherein said accessing the state record comprises: searching a databaseof state records utilizing an identifier for the process; identifyingthe state record based on the state record including the identifier forthe process; and selecting the state record based on a confidence scorefor the state record meeting a confidence threshold.
 4. The method asrecited in claim 1, wherein the state record indicates a poor estimatedsignal condition for a particular antenna, and wherein the methodfurther comprises: measuring a current signal condition of theparticular antenna; and determining whether to disable the particularantenna based on the current signal condition.
 5. The method as recitedin claim 4, further comprising: disabling the particular antenna if thecurrent signal condition indicates a poor signal condition; ormaintaining the particular antenna as active if the current signalcondition indicates a good signal condition.
 6. The method as recited inclaim 1, wherein said configuring the one or more antennas is performedindependent of a current observation of a signal condition of the one ormore antennas.
 7. The method as recited in claim 1, wherein the staterecord is generated based on a calibration process performed on adifferent device.
 8. A wireless device comprising: a sensor system; aset of antennas; and a connectivity module implemented to: detect, basedon a process that resides on the wireless device, an optimization eventindicating that the set of antennas of the wireless device are to beoptimized for wireless communication; access a state record thatidentifies the process and that specifies a performance parameter foreach antenna; and configure one or more of the antennas based on theperformance parameter, including at least one of to activate an antennabased on its respective performance parameter, or deactivate an antennabased on its respective performance parameter.
 9. The wireless device asrecited in claim 8, wherein to detect the optimization event is based onan indication that the process is launched on the wireless device, theprocess comprising one or more of an application or a system process.10. The wireless device as recited in claim 8, wherein to access thestate record comprises to: search a database of state records utilizingan identifier for the process; identify the state record based on thestate record including the identifier for the process; and select thestate record based on a confidence score for the state record meeting aconfidence threshold.
 11. The wireless device as recited in claim 8,wherein the state record indicates a poor estimated signal condition fora particular antenna, and wherein the connectivity module is furtherimplemented to: measure a current signal condition of the particularantenna; and determine whether to disable the particular antenna basedon the current signal condition.
 12. The wireless device as recited inclaim 11, wherein the connectivity module is further implemented to:disable the particular antenna if the current signal condition indicatesa poor signal condition; or maintain the particular antenna as active ifthe current signal condition indicates a good signal condition.
 13. Thewireless device as recited in claim 8, wherein to configure the one ormore antennas is performed independent of a current observation of asignal condition of the one or more antennas.
 14. The wireless device asrecited in claim 8, wherein the state record is generated based on acalibration process performed on a different device.
 15. A systemcomprising: one or more processors implemented at least in part inhardware; one or more computer-readable storage media storinginstructions that are executable by the one or more processors to:detect, based on a process that resides on a wireless device, anoptimization event indicating that a set of antennas of the wirelessdevice are to be optimized for wireless communication; access a staterecord that identifies the process and that specifies a performanceparameter for each antenna; and configure one or more of the antennasbased on the performance parameter, including at least one of toactivate an antenna based on its respective performance parameter, ordeactivate an antenna based on its respective performance parameter. 16.The system as recited in claim 15, wherein to detect the optimizationevent is based on an indication that the process is launched on thewireless device, the process comprising one or more of an application ora system process.
 17. The system as recited in claim 15, wherein toaccess the state record comprises to: search a database of state recordsutilizing an identifier for the process; identify the state record basedon the state record including the identifier for the process; and selectthe state record based on a confidence score for the state recordmeeting a confidence threshold.
 18. The system as recited in claim 15,wherein the state record indicates a poor estimated signal condition fora particular antenna, and wherein the instructions are furtherexecutable by the one or more processors to: measure a current signalcondition of the particular antenna; and determine whether to disablethe particular antenna based on the current signal condition.
 19. Thesystem as recited in claim 18, wherein the instructions are furtherexecutable by the one or more processors to: disable the particularantenna if the current signal condition indicates a poor signalcondition; or maintain the particular antenna as active if the currentsignal condition indicates a good signal condition.
 20. The system asrecited in claim 15, wherein to configure the one or more antennas isperformed independent of a current observation of a signal condition ofthe one or more antennas.